KR100562406B1 - Focusing method of digital camera - Google Patents

Abstract

 The present invention relates to a method for adjusting the focus of a digital camera. The focusing method of a digital camera according to the present invention includes driving a focusing motor in units of steps to find a position of a focus lens having a largest focus value proportional to a high frequency content of an image signal, comprising: (a) a focus value detecting step; (b) focusing lens shift step; (c) determining a focus adjustment state; And (d) focus state emphasis step. In the step (a), the focus value is detected while moving the focus lens by one step from the reference position in one direction. In the step (b), the position of the focus lens is moved to the current position by manual operation. In the step (c) it is determined the focus adjustment state at the current position. In step (d), the focus state is emphasized according to the focus adjustment state.

Description

Focusing method of digital camera {Focusing method of digital camera}

1 is a graph illustrating a focus value according to a position of a focus lens in a focus adjusting method of a conventional digital camera.

Figure 2 is a perspective view showing the front and top appearance of the digital camera according to the present invention.

FIG. 3 is a rear view illustrating a rear shape of the digital camera of FIG. 2.

4 is a diagram illustrating an incident side structure of the digital camera of FIG. 2.

5 is a block diagram showing the overall configuration of the digital camera of FIG.

6 is a flowchart illustrating a photographing control algorithm of the microcontroller of FIG. 5.

7 is a flowchart schematically illustrating a focus adjustment method of a digital camera as a preferred embodiment of the present invention.

8A and 8B are graphs schematically illustrating a focus value and a first derivative of a focus value according to a position of a focus lens according to the focus adjustment method of the digital camera of FIG. 7.

9 is a flowchart schematically illustrating a focus adjustment method of a digital camera according to another exemplary embodiment of the present invention.

The present invention relates to a method for controlling a digital camera, and more particularly, to a method for adjusting a focus of a digital camera in which a focus control motor is driven in steps to find a position of a focus lens having a largest focal value proportional to a high frequency content of an image signal. It is about.

1 is a graph illustrating a focus value according to a position of a focus lens in a focus adjusting method of a conventional digital camera.

In a focusing method performed by a conventional digital camera, a TTL (Through the Lens) method of focusing by analyzing a high frequency component (FV, Focus Value) of an image of a subject input while moving a focus lens is focused. Phosphorus so called high frequency climbing is used.

When the focus lens is in the focus position, the outline of the subject image is sharpest. That is, as shown in FIG. 1, the focus value of the subject image is maximized at the focus position of the focus lens. The focus value tends to increase as the focus lens approaches the focus position, and the focus value tends to decrease as it moves away from the focus position through the focus position. In the TTL method, the focus value is detected by focusing by inverting the focus value from the increasing tendency to the decreasing tendency.

The graph of the focus value according to the position of the focus lens used in the focusing method of the conventional digital camera may have a shape that increases and decreases linearly about the focus position m as shown. Here, DS denotes the number of position steps of the focusing motor, and FV denotes the focus value, that is, the high frequency content of the video signal.

As the focus adjusting method, an auto focus adjusting method in which the camera automatically determines the focusing position and moves the focus lens to the focusing position may be used. However, if necessary, a manual focusing method may be used in which a user may determine the focusing position while directly looking at a screen display device such as an LCD and operate the focusing lens to move to the focusing position. However, in the case of the manual focusing method, it is difficult for a user to determine a clear confocal state in a conventional digital camera using a small screen display device.

In order to solve this problem, the manual focusing method disclosed in Japanese Patent Laid-Open No. 2002-72332 can be used as the manual focusing method of the digital camera. Here, a separate focusing information display means is provided and the focusing information is displayed to the user through the focusing information display means, and the user can easily focus while checking the focus state.

Alternatively, as another example of a manual focusing method of a conventional digital camera, the distance data of the subject is presented in an on-screen display (OSD) in the form of a bar graph, so that the user can easily determine the focus point position. do.

However, in the case of the focus adjustment methods, a separate focus information display means is required, or when the focus information is displayed on the screen by the OSD, the OSD covers the small display screen so that the user displays it on the screen display device. There is a problem that can not properly check the screen.

The present invention is to solve the above problems, to provide a method for adjusting the focus of the digital camera to find the position of the focus lens having the largest focus value proportional to the high frequency content of the video signal by driving the focus control motor in steps. The purpose.

Focusing method of the digital camera according to the present invention for achieving the above object is to find the position of the focusing lens having the largest focus value in proportion to the high frequency content of the video signal by driving the focusing motor in steps, ( a) focus value detection step; (b) focusing lens shift step; (c) determining a focus adjustment state; And (d) focus state emphasis step.

In the step (a), the focus value is detected while moving the focus lens by one step from the reference position in one direction. In the step (b), the position of the focus lens is moved to the current position by manual operation. In the step (c) it is determined the focus adjustment state at the current position. In step (d), the focus state is emphasized according to the focus adjustment state.

Preferably, the focus value is obtained by integrating a value obtained by high pass filtering based on a preset cutoff frequency.

The focus adjustment state preferably includes a confocal state determined to be in focus and a blur state determined to be out of focus. At this time, in the graph of the focus value with respect to the position of the focus lens, it is preferable that the region between the inflection point and the inflection point of the focus value is in the confocal state and the other region is in the blurring state.

Alternatively, the focus adjustment state may be determined by the inclination of the focus value of the focus value graph based on the difference between the focus value of the current position and the focus value at the previous step position. At this time, it is preferable that the focus adjustment state is a blur state when the inclination of the focus value is smaller than the first reference value, and is in a confocal state when the inclination value is larger than the second reference value which is larger than the first reference value.

The step (d) may include: (d1) emphasizing the clarity of the video signal by high-pass filtering the video signal when the focus control state is a confocal state; And (d2) at least one of enhancing the blur of the video signal by performing low pass filtering on the video signal when the focus control state is a blur state.

According to another aspect of the present invention, a method for adjusting a focus of a digital camera includes driving a focusing motor in units of steps to find a position of a focus lens having a largest focus value proportional to a high frequency content of an image signal. Detecting a focus value proportional to the high frequency content of the image signal while moving the predetermined step by one step from the reference position; (b) finding a maximum focus point position that is a position of a focus lens having a maximum focus value; And (c) moving the position of the focus lens to the maximum focus value position.

The focus value is preferably obtained by integrating a value obtained by high frequency filtering of a video signal based on a preset cutoff frequency.

In the recording medium according to another aspect of the present invention, a program that implements a method for adjusting the focus of the digital camera is recorded.

In the digital camera according to another aspect of the present invention, a focus adjustment method of the digital camera is applied.

According to the present invention, it is possible to determine the focus by obtaining a focus value having a characteristic in which the inclination is clearly distinguished, and to emphasize the focus adjustment state thereby, to more clearly determine the focusing area and the blur area.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing the front and top appearance of the digital camera according to the present invention.

Referring to the drawings, in front of a conventional digital camera 1, a microphone (MIC), a self-timer lamp 11, a flash 12, a shutter button 13, a mode dial 14, a function-selection button 15, the shooting-information display unit 16, the viewfinder 17a, the function-block button 18, the flash-light amount sensor 19, the lens unit 20, and the external interface unit 21.

In the self-timer mode, the self-timer lamp 11 operates for a set time from when the shutter button 13 is pressed to when the shutter is operated. The mode dial 14 is used to select and set various modes, for example, a still image shooting mode, a night scene shooting mode, a movie shooting mode, a playback mode, a computer connection mode, and a system setting mode. . The function-selection button 15 is used for the user to select one of the operation modes of the digital camera 1, for example, a still image shooting mode, a night view shooting mode, a moving picture shooting mode, and a playback mode. The shooting-information display section 16 displays information of each function related to shooting. The function-block button 18 is used for the user to select each function displayed on the shooting-information display unit 16.

FIG. 3 is a rear view illustrating a rear shape of the digital camera of FIG. 2.

Referring to the drawings, behind the conventional digital camera 1, a speaker SP, a power button 31, a monitor button 32, an auto-focus lamp 33, a viewfinder 17b, a flash standby lamp (34), color LCD panel 35, OK / Delete button 36, enter / playback button 37, menu button 38, wide angle-zoom button 39w, telephoto ( telephoto) -zoom button 39t, up-move button 40up, right-move button 40ri, down-move button 40do, and left-move button 40le.

The monitor button 32 is used by the user to control the operation of the color LCD panel 35. For example, when the user presses the monitor button 32 first, an image of the subject and shooting information thereof are displayed on the display panel 35, and when the user presses the second button, only the image of the subject is displayed on the display panel 35. When pressed, the power applied to the display panel 35 is cut off. The auto-focus lamp 33 operates when the auto focusing operation is completed. The flash standby lamp 34 operates when the flash 12 (in FIG. 2) is in an operation standby state. The confirm / delete button 36 is used as a confirm button or a delete button in the process of setting each mode by the user. The enter / playback button 37 is used for inputting data from the user or for a function such as stopping or playing in the playback mode. The menu button 38 is used to display the menu of the mode selected in the mode dial 14. The up-movement button 40up, the right-movement button 40ri, the down-movement button 40do, and the left-movement button 40le are also used in the process of setting each mode by the user.

4 is a diagram illustrating an incident side structure of the digital camera of FIG. 2. 5 is a block diagram showing the overall configuration of the digital camera of FIG.

Referring to the drawings, the optical system OPS including the lens unit 20 and the filter unit 41 optically processes light from a subject. The lens unit 20 of the optical system OPS includes a zoom lens ZL, a focus lens FL, and a compensation lens CL.

When the user presses the wide angle-zoom button (39w in FIG. 3) or the telephoto-zoom button (39t in FIG. 3) included in the user input unit INP, a corresponding signal is output to the microcontroller 512. ) Is entered. Accordingly, as the microcontroller 512 controls the lens driver 510, the zoom motor M _Z is driven to move the zoom lens ZL. That is, when the wide angle-zoom button (39w in FIG. 3) is pressed, the focal length of the zoom lens ZL is shortened to widen the angle of view, and the telephoto-zoom button 39t is When pressed, the focal length of the zoom lens ZL becomes long and the angle of view becomes narrow. According to such a characteristic, the microcontroller 512 may obtain an angle of view for the position of the zoom lens ZL from the design data of the optical system OPS. Here, since the position of the focus lens FL is adjusted while the position of the zoom lens ZL is set, the angle of view is hardly influenced by the position of the focus lens FL.

On the other hand, when the focus is automatically or manually on the subject, the current position of the focus lens FL changes with respect to the subject distance Dc. Here, since the position of the focus lens FL is adjusted while the position of the zoom lens ZL is set, the subject distance Dc is affected by the position of the zoom lens ZL. In the auto focus mode, the focus control motor M _F is driven by the microcontroller 512 controlling the lens driver 510. Accordingly, the focus lens FL is moved from the front to the rear, and in this process, the position of the focus lens FL having the highest high frequency content of the image signal, for example, the position step of the focus control motor M _F. The number is set.

The compensation lens CL serves to compensate for the overall refractive index and is not driven separately.

Reference numeral M _A denotes a motor for driving an aperture (not shown). Here, the rotation angle of the diaphragm drive motor M _A varies depending on the case of the designated exposure mode and the case where it is not. The designated exposure mode refers to a mode for setting the exposure amount of the digital camera to the average brightness of the designated detection area when the desired area of the target area matches the designated detection area displayed on the display panel 35 of the digital camera. Say.

In the filter portion 41 of the optical system OPS, an optical low pass filter (OLPF) removes high frequency optical noise. Infra-Red cut filters (IRFs) block infrared components of incident light.

The photoelectric conversion unit (OEC) of a charge coupled device (CCD) or a complementary metal-oxide-semiconductor (CMOS) converts light from an optical system (OPS) into an electrical analog signal. Here, the digital signal processor 507 controls the timing circuit 502 to control the operation of the photoelectric converter OEC and the Correlation Double Sampler and Analog-to-Digital Converter (CDS-ADC) element 501. The CDS-ADC element 501 as an analog-to-digital converter processes the analog signal from the photoelectric converter (OEC), removes the high frequency noise, adjusts the amplitude, and converts the analog signal into a digital signal. The digital signal processor 507 processes the digital signal from the CDS-ADC element 501 to generate a digital image signal classified into luminance and chroma signals.

The light emitting portion LAMP driven by the microcontroller 512 includes a self-timer lamp 11, an auto-focus lamp (33 in FIG. 3) and a flash standby lamp (34 in FIG. 3). The user input unit INP includes a shutter button (13 in FIG. 2), a mode dial (14 in FIG. 2), a function-selection button (15 in FIG. 2), a function-block button (18 in FIG. 2), a monitor button ( 32 in FIG. 3), OK / Delete button (36 in FIG. 3), Enter / Playback button (37 in FIG. 3), Menu button (38 in FIG. 3), Wide-Zoom button (39w in FIG. 3), Tele- Zoom button (39t in FIG. 3), up-move button (40up in FIG. 3), right-move button (40ri in FIG. 3), down-move button (40do in FIG. 4), and left-move button (FIG. 3) 40le).

The digital video signal from the digital signal processor 507 is temporarily stored in the DRAM (Dynamic Random Access Memory) 504. The EEPROM (Electrically Erasable Programmable Read Only Memory) 505 stores algorithms and setting data necessary for the operation of the digital signal processor 507. The memory card of the user is attached to or detached from the memory card interface 506.

The digital image signal from the digital signal processor 507 is input to the LCD driver 514, whereby the image is displayed on the color LCD panel 35.

On the other hand, the digital video signal from the digital signal processor 507 can be transmitted by serial communication via a universal serial bus (USB) connection 21a or an RS232C interface 508 and its connection 21b, and a video filter ( 509 and the video output unit 21c can be transmitted as a video signal.

The audio processor 513 outputs the audio signal from the microphone MIC to the digital signal processor 507 or the speaker SP, and outputs the audio signal from the digital signal processor 507 to the speaker SP.

On the other hand, the microcontroller 512 drives the flash 12 by controlling the operation of the flash controller 511 according to the signal from the flash-light amount sensor 19.

6 is a flowchart illustrating a photographing control algorithm of the microcontroller of FIG. 5.

The photographing control algorithm of the microcontroller 512 of FIG. 5 will be described with reference to FIGS. 2 to 6 as follows. Here, the shutter button 13 included in the user input unit INP has a two-stage structure. That is, after the user operates the wide-zoom button 39w and the tele-zoom button 39t, the S1 signal from the shutter button 13 is turned on by pressing the shutter button 13 only one step, and 2 When the button is pressed all the way, the S2 signal from the shutter button 13 is turned on. Thus, the photographing algorithm of FIG. 5 starts when the user presses the shutter button 13 one step (step 101). Here, the current position of the zoom lens ZL is already set.

First, the remaining amount of the memory card is examined (step 102), and it is checked whether or not the capacity of the digital video signal can be recorded (step 103). If it is not a recordable capacity, it is indicated that the capacity of the memory card is insufficient (step 104). In the case of a recordable capacity, the following steps are performed.

First, an Automatic White Balance (AWB) mode is performed to set the relevant parameters (step 105). Next, an automatic exposure (AE) mode is performed, whereby the exposure amount for incident luminance is calculated, and the aperture driving motor M _A is driven in accordance with the calculated exposure amount (step 106). Next, an automatic focusing (AF) mode is performed to set the current position of the focus lens FL (step 107).

Next, it is checked whether the S1 signal, which is the first-stage signal from the shutter button 13, is on (step 108). If the S1 signal is not On, the execution-program is terminated because there is no user's intention of shooting. If the S1 signal is On, the following steps are continued.

First, it is checked whether the S2 signal is on (step 109). If the S2 signal is not on, the user has not pressed the second stage of the shutter button 13 for shooting, so the execution-program is moved to step 106 above.

If the S2 signal is on, the user presses the second stage of the shutter button 13 for shooting, and thus the shooting operation is performed (step 110). That is, the digital signal processor 507 is operated by the microcontroller 512, and the photoelectric conversion unit OEC and the CDS-ADS 501 are operated by the timing circuit 502. Next, the image data is compressed (step 111) to generate a compressed image file (step 112). After the generated image file is stored in the user's memory card from the digital signal processor 507 via the memory card interface 506 (step 113), execution of the algorithm is terminated.

According to an embodiment, the microcontroller 512 of FIG. 5 does not exist separately, and the imaging control algorithm performed by the microcontroller 512 described above may be processed by the digital signal processor 507 of FIG. 5. will be.

7 is a flowchart schematically illustrating a focus adjustment method of a digital camera as a preferred embodiment of the present invention. 8A and 8B are graphs schematically illustrating a focus value and a first derivative of a focus value according to a position of a focus lens according to the focus adjustment method of the digital camera of FIG. 7.

Referring to the drawings, the focusing method 200 of a digital camera is to find a position of a focusing lens having the largest focus value in proportion to the high frequency content of an image signal by driving the focusing motor in steps of (a) the focus value. Detection steps S202 and S203; (b) focusing lens shift step (S204); (c) focusing state determination step S206; And (d) focus state emphasis steps S207 and S208.

The method 200 of adjusting the focus of a digital camera according to the present embodiment relates to a manual focus adjusting method in which the focus is adjusted by an operation of a manual focus adjusting button from the outside by a user. The purpose of this report is to make it easy to determine the current focusing state.

That is, the manual focus adjusting method performed in S201 to S208 of the present embodiment is performed when the manual focus adjusting button is pressed by the determination (S201) of whether the manual focus adjusting button is pressed. For this purpose, it is preferable that a manual focus button is provided in a conventional digital camera. The focus button is a near button for focusing in a direction close to a far button for focusing in a direction far from the camera. near button).

This manual focusing method is a function mainly used when there is a subject at a fixed distance, and may provide a function according to a fixed distance corresponding to infinity, 2.5M, 1M, and the like. In particular, this function is recommended to be used when auto focusing is not possible (dark subjects, monochromatic subjects, etc.).

In the method 200 for adjusting the focus of a digital camera according to the present embodiment, the focusing motor is driven in units of steps according to the operation of the par or near button to determine the position of the focus lens having the largest focus value in proportion to the high frequency content of the image signal. Find. In this case, the focus value may be obtained by integrating a value obtained by high pass filtering the image signal based on the cutoff frequency with respect to the entire focus area.

The focus area is an area for obtaining a focus value among the entire video signals, but the entire video signal area may be the focus value. However, it may be more efficient to use only the area displayed on a specific area of a part of the screen display device as the focus area. In particular, the focus area may be positioned at the screen center in a size of 1/4 in a horizontal direction and 1/3 in a vertical direction of the entire screen of the screen display device.

In the above steps (a) and (S203), the focus value is detected while moving the focus lens by a predetermined step in one direction from the reference position. To this end, the focus difference motor is calculated by driving the focus control motor M _F while moving the focus lens FL from the reference position, that is, from the current position to the set end position. In this case, the focus value, which is a high frequency content of the image signal, is calculated while the focus control motor M _F is driven by the number of first steps, for example, eight steps, until the current position of the focus lens FL becomes the end position. .

In this case, the focus value is preferably obtained by high-pass filtering on the basis of a high cutoff frequency as compared to the case of having a curve as shown in FIG. 1. To this end, in the present embodiment, a cutoff frequency of any one of frequencies greater than 1/100 and less than 1/10 of a sampling frequency for image signal processing is obtained, and the image signal is obtained by high-pass filtering based on the cutoff frequency. It is desirable to find the focus value by integrating the values.

As shown in FIG. 8A, a graph showing a focus value obtained from a high frequency component by high pass filtering by a cutoff frequency having a larger value than in a normal case is shown in FIG. 8A, and FIG. 8B is a first system of the focus value. Differential graph is shown. In this case, it can be seen that the confocal region has a larger slope than the conventional case and the confocal region is clearly revealed. At this time, an inflection point at which the second derivative value becomes zero is formed at the position of the focus lens where the derivative value of the focus value is the maximum and minimum value, and the region between the inflection point and the inflection point becomes the confocal region, and the region other than the confocal region. This can be a blur area.

In the step (b) (S204), the position of the focus lens is moved to the current position by manual operation of the manual focus adjustment button. In step (c) (S206), it is determined the focus adjustment state at the current position.

At this time, it is preferable that the focus adjustment state comprises a focal point state determined to be focused and a blur state determined to be out of focus. At this time, in the graph of the focus value with respect to the position of the focus lens as shown in Figs. 8A and 8B, it is preferable that the area between the inflection point and the inflection point of the focus value is in the confocal state and the other area is in the blur state.

As another method of determining the focus adjustment state, the focus adjustment state at the current position may be determined by the tilt of the focus value of the focus value graph due to the difference between the focus value at the current position of the focus lens and the focus value at the previous step position. Could be At this time, it is preferable that the focus adjustment state is a blur state when the inclination of the focus value is smaller than the first reference value, and is in a confocal state when the inclination value is larger than the second reference value which is larger than the first reference value. This utilizes the tendency that the slope in the confocal region has a larger value than the slope in the blur region, as shown in FIGS. 8A and 8B.

At this time, in the present embodiment, it is preferable that the first reference value, which is the upper limit of the small slope of the blur region, is 0.3 per step, and the second reference value, which is the lower limit of the large slope of the confocal region, is 5.0 per step.

In the step (d) (S207, S208), the focus state is emphasized according to the focus adjustment state, the step (d1) of emphasizing the sharpness when the focus adjustment state is a confocal state and the focus adjustment state is blurry It is preferable to have at least one of (d2) step (S208) to emphasize the blur.

At this time, in the step (d1) (S207), when the focus adjustment state is the confocal state, the image signal is high-pass filtered to emphasize the sharpness of the image signal. In the step (d2) (S208), when the focus adjustment state is a blurring state, low-pass filtering of the video signal is emphasized to emphasize the blurring of the video signal.

That is, in the step (d) of emphasizing the focus state, when the focus adjustment state is the confocal state, the image signal is high-frequency filtered to emphasize the sharpness of the image signal (S207), or the focus adjustment state is the blur state. The video signal is low-pass filtered to emphasize the blur of the video signal (S208), or when the focus adjustment state is in the confocal state, the video signal is high-pass filtered to emphasize the sharpness of the video signal (S207), and the focus is adjusted. If the state is cloudy, low-pass filtering of the video signal may emphasize the blur of the video signal (S208).

In this case, the sharpness in the confocal region may be further emphasized by using a larger value of the cutoff frequency in the high pass filtering in the confocal region than in the low frequency pass filtering in the blur region.

In addition, the low pass filter and the high pass filter for the implementation of the present invention, using a filter included in the LCD driver for driving the LCD as a screen display device, or to adjust the sharpness (sharpness) of the LCD driver, etc. It may be implemented by setting a sharpness adjustment constant stored in a register for the image, or by using an image processing block inside the digital signal processor 507 of FIG. 5.

If it is not pressed by determining whether the manual focus button is pressed (S201), it is determined whether the S2 shutter button is pressed (S209), and when the button is pressed (S210), shooting is performed (S210) and the manual focus mode ends. do.

9 is a flowchart schematically illustrating a focus adjustment method of a digital camera according to another exemplary embodiment of the present invention.

Referring to the drawings, the method 300 of focusing a digital camera is to find a position of a focus lens having the largest focus value proportional to a high frequency content of an image signal by driving a focus control motor in steps of steps. Detection steps S302 and S303; (b) finding the focus lens position of the maximum focus value (S304); And (c) moving to the focal lens maximum focal point position (S305).

The focus control method 300 of the digital camera according to the present embodiment is an auto focus adjustment method in which focus adjustment is performed by an operation of an auto focus adjustment button from the outside by a user, and corresponds to a maximum focus value internally of the digital camera. Find the position of the focus lens and move the focus lens to that position so that you can capture the image. At this time, in the description of the present embodiment, the same components having the same function as the manual focus adjustment methods shown in FIGS. 7, 8A, and 8B use the same reference numerals as performing the same functions, and detailed descriptions thereof. Description is omitted.

In the above (a) steps S302 and S303, a focus value proportional to the high frequency content of the image signal is detected while moving the focus lens by one step from the reference position in one direction. To this end, a frequency of any one of frequencies greater than 1/100 and less than 1/10 of a sampling frequency for processing a video signal is set as a cutoff frequency, and a focus value proportional to a high frequency content whose set frequency is a cutoff frequency is detected. .

To this end, the focus difference motor is calculated by driving the focus control motor M _F while moving the focus lens FL from the reference position, that is, from the current position to the set end position. At this time, the focus control motor M _F is driven by the first step number, for example, 8 step number, until the current position of the focus lens FL becomes the end position, and the focus value, which is a high frequency content of the image signal, is read. (S302). At this time, as in the embodiment of FIG. 7, the focal value is preferably obtained from the graphs shown in FIGS. 8A and 8B.

In the step (b) (S304) to find the maximum focus value position which is the position of the focus lens with the maximum focus value. As a method of finding the position of the focus lens of the maximum focus value, various methods of finding the maximum focus value used in the conventional auto focusing method may be used. One example that can be used in this embodiment is as follows.

First, the focus lens FL is moved to the position of the maximum focus value among the focus values calculated in units of the first number of steps, and then the second number of steps smaller than the first number of steps, for example, based on the position of the maximum focus value. Focus values at positions before and after the 4 step number are measured and compared. That is, the position of the maximum value among the two maximum measured values and the newly measured values becomes the position of the new maximum focus value. Finally, the focus values are measured and compared at positions before and after the third step number, for example, two step numbers smaller than the second step number, based on the position of the new maximum focus value. In other words, the position of the maximum focus value and the largest value among the two newly measured values becomes the position of the focus lens of the final maximum focus value.

In the step (c) (S305), the position of the focus lens is moved to the position of the maximum focus value obtained in the step (b) (S304). In addition, when the S2 button is pressed at the position of the focus lens thus obtained, an image is taken (S310), and the auto focus adjustment mode is terminated.

The method of adjusting the focus of a digital camera according to the present invention is not only a digital camera, but also a digital still camera (Digital Still Camera, DSC), a digital video camera (DVC), a mobile phone that require automatic or manual focus adjustment. It can be applied to various image acquisition devices such as a camera (phone camera). However, in the present specification, the present invention is disclosed based on a digital still camera as a typical example to which the present invention may be applied.

According to the method for adjusting a focus of a digital camera according to the present invention, a focus value having a characteristic in which a slope is clearly distinguished may be obtained to determine a focus, and thus a confocal area and a blur area may be more clearly determined.

In addition, the image data in the blur region passes through the low pass filter (LPF) to emphasize the blur, and the image data in the focus region passes through the high pass filter (HPF) to emphasize the sharpness to more clearly determine the focus state. can do.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, it is merely an example, and those skilled in the art may realize various modifications and equivalent other embodiments therefrom. I can understand. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

Claims (12)

In the method of adjusting the focus of a digital camera to drive the focus control motor in units of steps to find the position of the focus lens having the largest focus value proportional to the high frequency content of the image signal, (a) detecting a focus value by moving the focus lens by a predetermined step in one direction from a reference position; (b) moving the position of the focus lens to a current position by manual operation; (c) determining a focus adjustment state at the current position; And and (d) emphasizing the focus state in accordance with the focus adjustment state. The method of claim 1, And the focus value is obtained by integrating a value obtained by high pass filtering the image signal based on a preset cutoff frequency. The method of claim 1, And the cutoff frequency is any one of frequencies greater than 1/100 and less than 1/10 of a sampling frequency for processing the video signal. The method of claim 1, The focus adjustment state, A focusing method of a digital camera, comprising a focusing state judged to be in focus and a blurring state determined to be out of focus. The method of claim 4, wherein In the graph of the focus value with respect to the position of the focus lens, the area between the inflection point and the inflection point of the focus value is in the confocal state, and the other area is the focus control method of the digital camera. The method of claim 1, The focus adjustment state, And a focus value tilt of a focus value graph based on a difference between a focus value of the current position and a focus value at a previous step position. The method of claim 6, The focus adjustment state, And if the focus value slope is less than the first reference value, the image is in a cloudy state, and if the focus value slope is greater than the second reference value, which is greater than the first reference value, the focusing method of the digital camera. The method according to claim 4 or 7, In step (d), (d1) emphasizing the clarity of the video signal by performing high frequency filtering on the video signal when the focus control state is a confocal state; And and (d2) at least one of emphasizing the blurring of the video signal by low-pass filtering the video signal when the focus adjustment state is a blurring state. delete delete A recording medium having recorded thereon a program that implements a method for adjusting the focus of a digital camera according to any one of claims 1 to 8. A digital camera to which the focus adjusting method of any one of claims 1 to 8 is applied.

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